PL239988B1 - Method for determining the abrasion resistance of floor underlays - Google Patents

Abstract

A method for determining the abrasion resistance of floor screeds, mainly made of concrete, in which a sample (1) of the floor screed is loaded with a wheel (2), and the sample (1) loaded with a wheel (2) is moved in mutually perpendicular directions and the resistance to abrasion is determined on the basis of the change in the volume of the sample (1), which is determined by the quotient of the change in mass and specific density, and is characterized by the fact that the sample (1) of the floor screed is subjected to a load by a solid rubber wheel (2) rotating in place, which samples (1) are pressed with a force of 600 to 1800 N and driven to a speed ranging from 30 to 60 rpm.

Description

PL 239 988 B1

Description of the invention

The subject of the invention is a method of determining the abrasion resistance of floor underlays, mainly made of concrete, under the pressure of a spinning wheel.

The wear of flooring materials is very often caused by the wheels of a solid tire spinning against the floor surface when excess engine power is transferred to the drive axle wheels, often when starting on surfaces with limited grip. In this situation, the wheel rotates around its axis, is pressed against the floor, but does not roll. As a result of the simultaneous significant increase in the temperature of the floor surface and friction, the surface structure of the material changes. This should be understood as a decrease in its near-surface strength as a result of the friction of a spinning wheel against a layer of material. As a result of this change, discoloration or chipping of the floor may occur.

There are known methods of determining the abrasion resistance of floor covering materials. One of them is the method of assessing abrasion resistance, which consists in placing a Boehme abrasive wheel on the test track on which a standard abrasive is poured. The disc is then rotated and the sample is subjected to load abrasion for a specified number of cycles. Wear due to abrasion is defined as the loss of sample volume according to PN-EN 13892-3: 2005 Methods of testing materials for floor screeds - Part 3: Determination of abrasion resistance according to Boehme.

In turn, the abrasion resistance by the Amsler method is determined by placing a sample on an Amsler disc on which a standard abrasive is sprinkled. Then the disc is rotated and the samples are subjected to abrasion for a specified number of cycles (PN-EN 14157: 2005).

There is a known BCA (British Cement Association) abrasion test apparatus, also known as the Chaplin Abrasion Apparatus. This method uses three road wheels of a specific shape, which rotate in a circle at a speed of 180 revolutions per minute under the pressure of 65 kg. Testing time for one sample is 15 minutes. Wear is determined on the basis of the measurement of the abrasion trace after 2850 rotations by rotating wheels according to PN-EN 13892-4: 2004 Methods of testing materials for floor screeds - Part 4: Determination of abrasion resistance according to BCA.

A device for testing the abrasion by the method under the pressure of a rolling wheel (RWA) is known. In the RWA method, a 500 χ 500 mm sample of an undercoat with a minimum thickness of 50 mm is placed on a special turntable and loaded with a steel wheel loaded with a force of 2000 N. The wheel moves along the surface of the sample in a longitudinal motion, performing 10,000 cycles (test time one sample is approx. 24 h), and the supporting table moves with the mounted sample in relation to the wheel in two mutually perpendicular directions, so that during the entire test the load acts on the desired surface. The result of the test is the average depth of the resulting sample loss, on the basis of which the volume of the rubbed material is determined in accordance with PN-EN 13892-5: 2004 Methods of testing materials for floor underlays - Part 5: Determination of resistance to abrasion of floor underlay materials under the pressure of a rolling wheel.

From the Polish patent application P.426540, a device for testing the abrasion resistance of a foundation, consisting of a housing and a test apparatus embedded in it, is known. The housing is a spatial structure, and the testing apparatus consists of two tables, lower and upper, moving perpendicular to each other and situated in two parallel planes one above the other, equipped with guides, two drive units interacting with the tables and consisting of a vertically located gear motor, wheels toothed gear mounted on the shaft of the geared motors and rack located on the tables, and the limit switches that change the direction of table movements. In addition, the device is equipped with an actuator located above the upper table in the vertical axis and a rolling wheel pressed by the actuator against the tested sample.

From the Polish description of the invention PL211940, a device for testing the abrasion resistance of floor underlays is known, including a grinding head and a gear motor coupled to it. The device consists of a casing consisting of a rectangular frame with guides inside, and a plate-shaped base, a carriage with guide sleeves slidably mounted in the guides of the frame, and a crank mechanism coupling the carriage with the frame. The grinding head and the gear motor are located on the carriage and pivotally coupled to each other via a spherical pin connecting the base of the grinding head to the drive shaft of the gear motor.

From the Polish patent application P.406401, there is known a device for testing the abrasion resistance of floor underlays, comprising a housing, a grinding head, a drive unit and a loading unit for the abrasive head. The housing is a frame consisting of racks connected to

With each other with the upper and middle crossbars, sleeves telescopically connected to the ends of the stands, feet connected to the sleeves and a removable plate detachably connected to the feet, and the drive unit is a motoreducer, gears consisting of a driving wheel mounted on a shaft of a motoreducer and a driven wheel mounted on on the main shaft, the main shaft is located in the symmetry axis of the grinding head and slidably seated in the thrust bearing, the disc is permanently connected with the driven wheel from above, and connected with the grinding head from the bottom through holes and pins, and a spherical joint connecting the base with the main shaft, and the assembly The loading one consists of a pneumatic cylinder attached to the upper crossbar, a strain gauge force gauge connected from the top to the piston rod of the pneumatic cylinder, and from the bottom it rests on the thrust ring and a thrust bearing mounted on the main shaft.

A device for determining the abrasion resistance of floor screeds is known from the Chinese application for the invention CN110031350. It consists of a base on which a concrete slab sample is attached in the form of a tile, and on which a vertical frame is located, in which a shelf is slid vertically, in which in the range of half of the right angle in the vertical axis, a rotating arm facing downwards is attached, at the lower end of which a hub is attached, to which a rotatable, pumped rubber wheel is attached, which by lowering the rotating arm is pressed against a fixed sample on the base concrete sleeper. The wheel mounted on the rotating arm after the concrete sleeper sample is adjustable along an arc determined by the axis length. The device is equipped with a gear motor for the vertical movement of the shelf, and a servo mechanism for the movement of the rotary arm. In the present solution, the wheel is rolled over a strictly defined area, which is a partial surface of the tested sample.

All the above-presented methods and devices for their implementation are not predisposed to determine the resistance of the floor base to wear resulting from the friction of a spinning wheel on its front surface. The above solutions cannot be used to test the wear of floor materials when the wheel rotates around its axis and is pressed against the floor, and does not roll.

The object of the invention is to develop a method for determining the abrasion resistance of floor underlay materials under the pressure of a spinning wheel.

The essence of the method of determining the abrasion resistance of floor underlays, according to the invention, is characterized by the fact that a sample of a floor underlay with dimensions of at least 150 χ 150 mm and a thickness of at least 40 mm is subjected to a force from 600 to 1800 N, driven and rotated in place at a speed of in the range from 30 to 60 rpm with a solid rubber wheel, under which, for the load on the desired area of the sample face, the loaded sample moves in mutually perpendicular directions, the abrasion resistance is determined on the basis of the volume change value a sample, which is determined by the quotient of the mass change and the specific density.

The advantage of the solution according to the invention is the ability to determine the wear of flooring materials when the wheel rotates around its axis, is pressed against the floor and does not roll. The above-mentioned specificity allows for the assessment of the wear model in which the floor chippings appear and changes in the subsurface structure and strength of the material as a result of a simultaneous significant increase in the temperature of the floor surface and friction as a result of the friction of the spinning wheel against the material layer.

The subject of the invention has been shown in the drawing, in which fig. 1 shows the system in which the subject of the invention is implemented in a side view, and fig. 2 shows the arrangement of fig. 1 in a top view.

The method of determining the abrasion resistance of floor screeds in an embodiment according to the invention consists in that a sample 1 of a screed with dimensions of at least 150 × 150 mm and a thickness of at least 40 mm is subjected to an axial load of 600 to 1800 N, driven and rotated in a place with a solid rubber wheel 2 under which, for the load on the desired area of the sample end face 1, the loaded sample 1 is moved in mutually perpendicular directions. In the above system, the driven wheel 2, pressed and held in place, spins on the sample 1. For the above implementation, sample 1 is placed on the table 3, which, with the sample 1 rigidly attached to it, against the axial pressure on the face of the sample 1 rotating in wheel 2, moves in two mutually perpendicular directions. The wheel 2 spinning over the sample 1 is rotatably fastened in the frame 4 located above the table 3, one end of which is rotatably fastened in the support 5, and the other is loaded

Claims (2)

The weight 6, which allows the sample to be loaded with a force from 600 to 1800 N. The wheel 2 is mounted in a hub rigidly fixed in the frame and is driven by the axis moved by a gear motor mounted on the frame 4. The gear motor drives the wheel 2 to the speed range from 30 to 60 rpm The table 3 is moved to such an extent that, throughout the test, the load acts on an area of 110 cm ² . Sample 1 to be tested should be clean and dried at a temperature of 70 ± 5 ° C to constant weight. Before the test, the volumetric density (p _b ) and the mass (m) of sample 1 are determined. After the measurement, the mass (m ^) of sample 1 is determined again and the wear due to abrasion under the pressure of spinning wheel 2 is calculated as the average reduction in the sample volume Δ7, from the formula: m -m _f ΔΥ = ----- ^L. Pb The wear model carried out by the method according to the invention is different from the known models, because it assumes that as a result of a simultaneous significant increase in the surface temperature of the floor and friction, the subsurface structure of the material changes, which causes a decrease in the subsurface strength as a result of the friction of the spinning wheel against the material layer. The wear pattern is sudden, often in the form of the floor chipping, and nothing like in the known methods in the form of gradual abrasion of the material from the surface of the floor underlay. Patent claims The method of determining the abrasion resistance of underlays, in which a sample of the underlay is loaded with a wheel, the sample loaded with a wheel is moved in mutually perpendicular directions, and the abrasion resistance is determined on the basis of the value of the change in sample volume, which is determined on the on the basis of the value of the sample volume change, which is determined by the quotient of the mass change and the specific density, characterized in that the floor screed sample (1) is subjected to a load of a solid rubber wheel (2) rotating in place, driven by a gear motor (7) and which the samples (1) are pressed with a force of 600 to 1800 N and driven to a speed in the range of 30 to 60 rpm. 2. The method according to p. The method of claim 1, characterized in that a sample (1) of an underlay with dimensions of at least 150 × 150 mm and a thickness of at least 40 mm is used.